KR800000902Y1 - Horizontal deflection circuit - Google Patents

Abstract

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Description

Horizontal output circuit

1 is a connection diagram of a conventional example.

2 is a waveform diagram for explanation thereof.

3 is a connection diagram of an example of the present invention.

The horizontal deflection circuit of the television receiver is configured as, for example, the first diagram. In other words, (1) is a horizontal oscillation circuit, (2) is a drive circuit, (3) is an output circuit table, and in the output circuit (3), a GCS 31 is provided as a switching element, and the anode is choked. The damper diode 35, the resonant capacitor 36, and the horizontal deflection coil 37 are connected to the power supply terminal 33 through the coil 32. (4) is a high voltage circuit. In the oscillation circuit 1, a horizontal pulse is supplied to the gate of the GCS 31 through the driving circuit 2 so that the GCS 31 is turned "on" and "off", and thus the GCS 31 is turned "on". When the anode current 1a as shown by the solid line in FIG. A flyback pulse as shown by the solid line in the figure is obtained and thus a horizontal deflection current is supplied to the deflection coil 37. At this time, the flyback pulse is supplied to the high voltage circuit 4 to form a high voltage.

In this case, however, due to an accident, discharge occurs at the time point t ₁ in the high voltage circuit 4, and the oscillation circuit 1 is triggered by the discharge pulse, which malfunctions, causing the GCS 31 to be "on" at time point t ₁ . In this case, since the anode current as shown by the dotted lines in Figs. 2a and b flows and becomes the anode voltage, the GCS 31 is destroyed at this time. The present invention is intended to prevent such an accident. Therefore, in the present invention, for example, as shown in FIG. 3, the pulse pf is taken out from the horizontal output circuit 3 in the flyback pulse period tf, and the driving pulse of the output circuit 3 is generated in the period tf by the pulse pf. Is clamped to a predetermined value so that the GCS 31 is houlded off.

That is, in the example of FIG. 3, transistors 21-23 are provided so that horizontal pulses from the oscillation circuit 1 are supplied to the primary coils of the transistors 24 through the transistors 21-23. At the same time, the diode 25 is connected between the secondary coil of the transformer 24 and the gate of the GCS 31, and the choke coil 26 is connected, and the drive circuit 2 is driven.

In addition, in the example of FIG. 3, the transformer 38 is provided instead of the choke coil 32 of FIG. 1, and the secondary coil of the transformer 38 is connected to the base of the transistor 51 for switches. The power supply terminal 28 is connected to the base of the transistor 21 through the resistor 52 again through the emitter collector of the transistor 51.

In such a configuration, it is assumed that the transistor 51 is not connected because it is simple. In this case, when the transistor 21 is turned "on" by the horizontal pulse from the oscillation circuit 1, the transistor 22 is turned "off" and the transistor 23 is turned "on". When the transistor 23 is turned "on", the secondary coil of the transformer 24 generates a voltage at the polarity of the drawing, and the current 51 is applied to the coil 26 through the diode 25 by the voltage. The GCS 31 is " off " due to the voltage generated at the same time as the secondary coil.

Then, when the transistor 21 is turned "off" by the horizontal pulse from the oscillation circuit 1, the transistor 22 is turned "on" and the transistor 23 is turned "off". Therefore, at this time, the secondary coil of the transformer 24 generates a voltage of reverse polarity with the surface thereof, but since there is a diode 25, it is not supplied to the GCS 31. However, at this time, since the current flowing through the coil 26 is cut off, the counter 26 generates a counter voltage in the polarity of the drawing, which is supplied to the GCS 31 so that the GCS 31 is "on".

Thus, the GCS 31 is turned "on" and "off" corresponding to the horizontal pulse in the oscillation circuit 1, so that the deflection current 37 is supplied to the deflection coil 37 as described in FIG. In this case, if a flyback pulse is obtained on the anode of the GCS 31 in the flyback period tf, a negative pulse pf is obtained for each period tf in the secondary coil of the transformer 38 at this time. Since the impulse pf is supplied to the transistor 51, the transistor 51 is turned "on" every period tf, and the base of the transistor 21 is clamped at a predetermined potential every period tf by this flyback pulse. Thus, the transistor 21 is honed to the "on" state every period tf by the flyback pulse.

Thus, the transistor 21 is forced to the "on" state by the flyback pulse in the flyback period tf. At this time, even if the oscillation circuit 1 malfunctions due to the discharge pulse of the high voltage circuit 4, the GCS 31 ) Does not " down on ", and therefore the GCS 31 can be protected from destruction by discharge pulses. Also, the configuration for doing so is simple and inexpensive.

As described above, the flyback pulse is returned to the driving circuit 2 and the GCS 31 is houlded in the " off " state in the period tf. However, the flyback pulse is returned to the oscillation circuit 1 to return the GCS 31 to " It may be called in the "off" state. In addition, in the above-described case, the horizontal output circuit is integrated with the horizontal deflection circuit and the high voltage circuit, but it is also applicable to the separate horizontal output circuit.

Claims (1)

A horizontal oscillation circuit, a driving circuit, and an output circuit, as shown in the drawings and described above in the main text, have flyback pulses taken out from the output circuits, and flyback pulses are fed back to the oscillation circuits or the drive circuits to output the output circuits. And a drive signal supplied to the circuit is clamped to a predetermined value during the flyback period so that the output circuit is turned "off".